Methods of optimizing chromatographic separation of polypeptides

The invention claimed is: 1. A method of optimizing purification of a target peptide, comprising (i) determining peptide-specific parameters of the target peptide and at least one product related impurity by a) chromatographically separating a mixture comprising the target peptide and at least one product related impurity; b) recording retention behaviour data of the target peptide and at least one product related impurity; c) fitting the retention behaviour data to a mathematical model represented by equation (1) to calculate the peptide-specific parameters v i and K i for the target peptide and at least one product related impurity: V R , i = V NR , i + ( 1 - ɛ ) ⁢ ɛ p ⁢ K d ⁢ K i ⁡ ( Λ z salt · c salt ) v i , ( 1 ) wherein Z salt is the charge of the counter ion, C salt is the counter ion concentration, Λ is the ionic capacity, ε is the porosity between particles, ε p is porosity, K d is the exclusion factor, V NR,i is the retention volume under non-retained conditions, V R,i is the retention volume, i is the index for the target peptide or at least one product related impurity, v i is the characteristic charge, and K i is the equilibrium constant; d) recording adsorption isotherm data of the target peptide from the mixture or in a sample without the least one product related impurity; and e) fitting the adsorption isotherm data to a mathematical model represented by equation (2) to calculate the peptide-specific parameter σ i for the target peptide: c i = q i K i [ c s Λ - ∑ i ⁢ ⁢ K d , i · q i · ( v i + σ i ) ] v i ( 2 ) wherein Λ is the ionic capacity, K d,i is the exclusion factor, σ i is the steric factor, v i is the characteristic charge, q i is the solid phase concentration of peptide, c i is mobile phase concentration of peptide, c S is the counter ion concentration and K i is the equilibrium constant, and i is the index for the target peptide; wherein the steric factor of the at least one product related impurity is assumed to be identical to the steric factor σ i for the target peptide; and (ii) simulating a chromatography using the calculated peptide-specific parameters v i , K i , and σ i to obtain optimized chromatography settings selected from the group consisting of loading solution and elution conditions for optimizing purification of the target peptide in a mixture with the at least one product related impurity; (iii) applying the obtained optimized chromatography settings to chromatographic separation of the target peptide from the at least one product-related